The present invention relates to remote convenience systems, and is particularly directed to a remote convenience method and apparatus that extends the range of operation of the system by reducing signal nulls.
Remote convenience systems are known in the art. One example type of a remote convenience system, known as a remote keyless entry (“RKE”) system, is designed to remotely lock and unlock doors of a vehicle such as a passenger car, SUV, or truck. An RKE system may also control other vehicle functions, such as remote start of the vehicle (useful in areas having cold winter weather), and horn chirp and light flashing (useful for finding your vehicle in a large and crowded parking area). An RKE system will typically include a small portable transmitter, referred to as a fob, carried by the vehicle operator, and a radio receiver installed in the vehicle. Pressing a button on the fob causes the fob to transmit a corresponding coded radio frequency (“RF”) command to the receiver. The receiver decodes the commands and controls vehicle systems so as to complete the commanded action.
It is helpful if the range of the RKE system is rather long so that certain functions (e.g. “remote start” and “vehicle locator” functions) can be initiated from a relatively long distance from the vehicle. U.S. Pat. No. 6,472,999 to Lin describes an RKE system that performs some functions at long distance, and others functions only at much shorter distances.
The range of operation of an RKE system is limited by the power of the RF signal generated by the transmitter in the fob, as well as by the quality of the communication path between the fob and the vehicle. Obstructions (particularly metal obstructions) within the vicinity of the communication path may attenuate the transmitted signal or create so-called ‘multipath’ reflections, either of which may diminish range of operation of the system.
In accordance with one aspect of the present invention, apparatus is provided for use in a vehicle convenience system. The apparatus includes a radio-frequency receiver having an antenna input adapted for connection to an antenna for receiving radio frequency signals, and includes a source of at least a first local oscillator frequency and a second local oscillator frequency, as well as a demodulator and a control circuit. The demodulator demodulates the signal received via the antenna input with the first local oscillator frequency to generate a first demodulated signal and, separately, demodulates the signal received via the antenna with the second local oscillator frequency to generate a second demodulated signal. The control circuit evaluates the first and second demodulated signals according to at least one criterion and, responsive to the evaluation, utilizes for control purposes one of the first and second demodulated signals.
In accordance with another aspect of the present invention the apparatus also includes a radio-frequency transmitter for use in connection with the receiver. The transmitter transmits an RE message modulated on a first carrier frequency, and also transmits an RF message modulated on a second carrier frequency.
In accordance with yet another aspect of the present invention, a method is provided for reducing signal nulls in vehicle control systems. The method includes the steps of transmitting a first signal at a first frequency and transmitting a second signal at a second, different frequency, receiving the first signal and the second signal, evaluating the received signals according to at least one criterion related to signal quality, and, in response to the evaluation, utilizing at least one of the first or second received signals to operate a vehicle convenience system.
In accordance with a further aspect of the present invention, apparatus is provided for use in a vehicle control system. A battery-powered radio transmitter transmits vehicle control messages on first and second radio frequencies separated from one another by selected frequency difference. An antenna is adapted for mounting on a vehicle, the antenna having a radiation pattern with signal nulls at different locations at the first and second radio frequencies. A receiver is adapted for mounting on a vehicle and is connected to the antenna for receiving radio frequency signals therefrom. The receiver includes a demodulator for demodulating the signal transmitted by the transmitter on the first radio frequency and the signal transmitted by the transmitter on the second radio frequency to thereby generate respective first and second demodulated signals. The receiver further includes a control circuit for controlling at least one vehicle system. The control circuit evaluates the first and second demodulated signals according to at least one criterion and utilizes for control purposes whichever of the signals is better quality, according to that criterion.
The foregoing and other features and advantages of the present invention will become apparent to those skilled in the art to which the present invention relates upon reading the following description with reference to the accompanying drawings, in which:
Referring to
The receiver 14 is mounted on a vehicle 20, and is connected to various vehicle subsystems 22, such as electric door locks, horn, and engine controls. When the operator presses a push button 16 on the fob 12, the controller 17 causes the transmitter 18 to broadcast a corresponding secure coded digital message to the receiver 14. The receiver 14 decodes the message and causes the subsystems 22 to perform the function associated with the fob button pressed by the operator.
Some RKE functions, e.g. remote start, door lock, or horn chirp, are desirably operable from long range. Further, vehicle operators expect their RKE system to exhibit a reasonably consistent range of operation at all locations around the vehicle. However, due to multipath reflections and signal attenuation caused by structure obstructions (both internal structures within the vehicle 20 and external structures in the vicinity of the vehicle 20), as well as directionality of the antenna associated with the receiver 14, there will inevitably be signal null locations around the vehicle. These null locations occur at particular angular locations around the vehicle depending on the vehicle structure and surroundings. Therefore, the null locations are referred to as “null angles.” At particular null angles about the vehicle, the signal reception will be impaired and thus the RKE system will exhibit a shorter range of operation.
When an RE signal is broadcast by the fob, the paths of the reflection/diffraction signals bounced from surrounding structure and through the vehicle to the receiving antenna will depend upon the wavelength of the RF signal. Thus, for a given vehicle design and location, the far field radiation pattern of the vehicular antenna will vary with the wavelength of the signal being received. In particular, the null angle of an antenna operating at one frequency will be different from the null angle at a different frequency.
According to the present invention, this frequency dependence is exploited to overcome the range inconsistency arising from the signal nulls. Two operating frequencies f1 and f2 are chosen so that the radiation patterns of the vehicular antenna, at those two frequencies, are different. Because the difference in the radiation patterns will be small if the two frequencies are close, f1 and f2 are preferably chosen so that the difference between the frequencies is sufficient to provide the desired different radiation patterns so as to reduce null effects. Specifically, the frequency difference will be chosen to be large enough that the nulls associated with the two frequencies will be found at different angular locations around the vehicle, as shown in
The transmitter 18 includes a modulator 30 and a carrier source 32. The carrier source 32 is designed to provide carrier frequency f1, or carrier frequency f2, as selected by controller 17 via control line 34. The carrier source 32 may take any of a variety of forms. It may, for example, comprise two switchable crystal-controlled oscillators, or a single oscillator either (a) with switchable impedance or filter (e.g. SAW filter) elements or (b) with a fixed frequency oscillator and a controllable frequency divider.
The carrier frequency of the transmitted secure coded digital message will match the frequency of the carrier frequency source. In the presently described embodiment of the invention, the modulator 30 is an amplitude-shift-keyed (“ASK”) modulator that amplitude modulates (typically, keys on and off) the carrier according to the content of the secure coded digital message. The resulting modulated RF signal is coupled to, and broadcast by, antenna 36. The invention would apply equally to a system using another type of modulation, such a frequency-shift-keyed (“FSK”) modulation.
The controller 17, in accordance with one example embodiment, is programmed so that, for each button actuation, the same secure digital message will be sent to the transmitter 18, and thereby transmitted, four times in succession. For the first two transmissions, controller 17 will cause carrier source 32 to supply carrier f1 and, for the last two transmissions, controller 17 will cause carrier source 32 to supply carrier f2. Thus the same message will be sent twice upon carrier frequency f1, and twice upon carrier frequency f2. The timing of the transmissions is illustrated in
In the example illustrated in
A receiver inside the vehicle is equipped to receive both sets of messages. An antenna 38 receives the RF signal broadcast by antenna 36, and supplies the resulting signal to a demodulator 40. A local oscillator (“LO”) signal from a local oscillator 42 is also provided to demodulator 40, which beats the received RF signal against the LO signal. The resulting intermediate frequency (“IF”) signal, which could be a frequency of zero where the demodulator is a direct demodulator, is filtered and otherwise processed within the demodulator to provide a baseband signal to the controller 44 for decoding and subsequent control of the vehicle subsystems 22. In the presently described example embodiment, the controller 44 is a programmed microcomputer.
The local oscillator 42 is designed to provide an LO signal of frequency f3, or an LO signal of frequency f4, as selected by controller 44 via control line 46. The frequencies f3 and f4 are displaced from the frequencies f1 and f2 by an amount equal to the chosen IF frequency whereby received signals on frequency f1 may be demodulated when LO frequency f3 is chosen, and signals on frequency f2 are demodulated when LO frequency f4 is chosen. The local oscillator 42 may take any of the designs previously discussed with respect to carrier source 32.
Controller 44, under program control, will cause local oscillator 42 to provide LO frequency f3 for some preset interval T1. Controller 44 will thereafter cause local oscillator 42 to provide LO frequency f4 for an interval T2, preferably equal to T1. Controller 44, again under program control, will cause local oscillator 42 to continue to alternate LO frequencies f3 and 14 in this manner (with a period shown as “Rx period” in
Demodulator 40 includes circuitry for measuring, either autonomously or under control of controller 44, the signal strength of the received signal during the polling process. The received signal strength measurement may be generated in any conventional fashion and may, for example, be generated as described in the aforementioned prior U.S. Pat. No. 6,472,999, which is hereby fully incorporated herein. The resulting received signal strength indication (“RSSI”) is provided to controller 44 for evaluation. The controller 44 uses the RSSI as a measure of the quality of the wake-up signal received from the fob 12, and adopts and responds to the frequency having the higher message quality. Thus, the communication system as a whole chooses whichever set of messages, those modulated upon frequency f1 or those modulated upon frequency f2, displays the highest RSSI under the then-extant circumstances. In the example of
In
Following the activities in step 58, the controller 44 at step 60 conditionally jumps back to step 52 if no wake-up signal was detected at RF1 or RF2 (i.e., the measured RSSI was below a noise threshold at both frequencies). Before repeating the process at step 52, however, the controller 44 will pause for some dwell time, which is 18 ms in the illustrated example.
If at least one message was detected, however (i.e., the RSSI was above the noise threshold at least at one of the polled frequencies), then program flow proceeds to another conditional in step 62. If it is determined in step 62 that only one valid wake-up signal was received, program flow continues to step 64 where that valid wake-up signal is acted upon. In step 64, the receiver is tuned to the frequency at which the valid wake-up signal was received, and the receiver awaits a valid data message from the fob 12 at that frequency. If a valid message is thereupon received (check sum correct, transmitter ID code correct, etc.) the resulting validated vehicle command contained in the message (e.g., a vehicle door lock or unlock command) is implemented by controller 44. The implementation of the command is accomplished in any conventional manner. For example, the controller 44 may send a suitable door lock control message to a vehicle “body control module” via a wired vehicle communication bus, e.g. a so-called “CAN” bus. The body control module will in turn operate the door lock in accordance with the command.
If it is determined in step 62, however, that valid wake-up signals were received both at RF1 and RF2, then program flow instead branches to step 66. In step 66, the RSSIs of RF1 and RF2 are compared, with that frequency subsequently being used whose RSSI was greater. If the RSSI of RF1 was greater than the RSSI of RF2, then program flow continues to step 68 where the receiver is tuned to f1 (LO set to f3) and the fob message is received at that frequency and the encoded vehicle command is implemented. If, on the other hand, the RSSI of RF1 is not greater than the RSSI of RF2 (meaning that the RSSI of RF2 is as great as, or greater than, the RSSI of RF2), then program flow continues to step 70 where the receiver is tuned to f2 (LO set to f4) and the fob message is received at that frequency and the encoded vehicle command implemented. The command receipt and implementation steps 68 and 70 are similar in content to step 64, except with respect to the frequency to which the receiver is tuned during receipt of the message.
After each of steps 64, 68, and 70, program flow reverts to the beginning of the cycle at step 52, whereupon, again under program control, receiver 14 will revert to the polling process and continue to alternate LO frequencies f3 and f4 as long as receiver 14 is listening for messages.
Various other embodiments are contemplated that may further improve performance of the system. For example, the antenna 38 could be a single antenna, as illustrated, with or without special tuning for each carrier frequency f1 and f2, or could instead be two or more separate antennae. If two antennae are provided, they will preferably be separated from one another physically by a certain distance and/or will have different polarizations. Such antenna diversity will overcome shadows directly caused by the vehicle structure behind the receiving antenna, and will also mitigate some RF fading. However, physical separation of the antennae will increase the size of the receiver or require that one antenna be mounted remote from the rest of the receiver. Sometime, this is not desired. Thus, the design choice will depend upon other system design constraints.
The described frequency diversity concept can also be applied to the other vehicle systems relying upon RF communications links such as, e.g., tire pressure monitor (“TPM”) systems. In a TPM system using the present concepts, the sensor inside the tire will transmit two frequencies and a receiver inside the vehicle will receive the two frequencies, measure signal quality via RSSI or some other criteria, and then use the higher quality signal. In response to the received message, the receiver will control a driver alert device, typically a warning light, according to the inflation state of the tires.
In the described embodiment only two frequencies are used, but the present invention is not limited to two frequencies. Frequency diversity systems using more than two frequencies can be constructed with the same principles described above.
From the above description of the invention, those skilled in the art will perceive improvements, changes and modifications. For example, the present invention has been described with reference to an RKE system. The invention is also applicable to other transmitter/receiver system such as tire pressure monitor system, other security systems such as home security systems, etc. Other measures of signal quality may be used instead of RSSI such as, e.g., data error rates or signal amplitude or frequency variability. Instead of using wake-up signals in the described manner, the messages may be received at each frequency and the signal quality measured directly from those received messages. Such improvements, changes and modifications within the skill of the art are intended to be covered by the appended claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US2013/026589 | 2/18/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/126305 | 8/29/2013 | WO | A |
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PCT/US2013/026589 International Search Report and Written Opinion, completed Apr. 3, 2013. |
Number | Date | Country | |
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20140354404 A1 | Dec 2014 | US |
Number | Date | Country | |
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61602141 | Feb 2012 | US |